Ten years ago, a package arrived at the lab of Dr. Jeff Lichtman, who is a professor of molecular and cellular biology at Harvard University. It contained a small brain sample. The sample was merely 1 cubic millimeter. 바카라It was less than a grain of rice, but we began to cut it and look at it, and it was really beautiful,바카라 Dr. Litchman said.
Despite its diminutive stature, it held thousands of cells and connections, like a mini-map of the human mind. Packed within this tiny piece resided 57,000 cells, 230 milimeters of intricate blood vessels, and a staggering 150 million synapses. This seemingly insignificant has become the 바카라Rosetta Stone바카라 for brain, unlocking a new chapter in our understanding of the brain and embarking on a decade-long odyssey to map its labyrinthine pathways.
The brain sample belonged to a patient with severe epilepsy. Dr. Lichtman's team meticulously sliced the sample into incredibly thin sections using a knife with a blade edge made of diamond. The sections were then embedded into a hard resin and sliced again, very thinly. 바카라About 30 nanometers, or roughly 1,000th of the thickness of a human hair. They were virtually invisible, if it weren바카라t for the fact that we had stained them with heavy metals, which made them visible when doing electron imaging,바카라 Dr. Litchman said.
These sections were then meticulously imaged using electron microscopy, resulting in a staggering 300 million individual images. Faced with this data deluge, researchers realised they need help with the data. They needed someone with the computational muscle to handle such a colossal undertaking.
Google at that time was working on a digital map of a fruit fly바카라s brain (released in 2019) and so Dr. Litchman figured that they have the required system for this job. He approached Viren Jain, a senior staff research scientist at Google. Jain saw the immense potential of Lichtman's data, 바카라There were 300 million separate images (in Harvard바카라s data)바카라. 바카라What makes it so much data is that you바카라re imaging at a very high resolution, the level of an individual synapse. And just in that small sample of brain tissue there were 150 million synapses.바카라
Jain바카라s team then used Google's vast computing resources and the power of AI. Jain and his team embarked on the task of processing the millions of images. To understand the pictures, scientists at Google used artificial intelligence (AI) to process and analyze them. They identified the types of cells in each picture and their connection. The effort resulted to an interactive 3D model of the brain tissue, which is the biggest dataset ever created at this level of detail. Google named it "Neuroglancer" and shared it online. Following, a study was published in the journal Science, with both Lichtman and Jain credited as coauthors.
The map itself was a box full of surprises. One particularly intriguing finding was the presence of pairs of neurons with an unusually high number of connections 바카라 far more than previously anticipated. 바카라This is kind of like if two houses on a block had 50 separate phone lines connecting them. What바카라s going on there? Why are they so strongly connected? We don바카라t know what the function or significance of this phenomenon is yet, we바카라re going to have to study it further,바카라 Jain said.
This unexpected finding hinted at a deeper level of complexity in neuronal communication, raising new questions about brain function and potentially opening doors to a better understanding of neurological disorders.
But what about mapping the entire human brain? Lichtman said that it would require data that's a thousand times larger, totaling 1 zettabyte. To put it in perspective, in 2016, that was the equivalent size of all internet traffic for the year, as per Cisco. Lichtman highlighted that, at present, not only storing such vast data would be challenging, but there's also no ethical way to obtain a perfectly preserved human brain.
While mapping a complete human brain remains a distant dream due to ethical considerations and technological limitations, the success of this project paves the way for future endeavors. The next frontier lies in mapping the entire brain of a mouse, a project estimated to require 500-1,000 times more data than the human sample. This ambitious undertaking will push the boundaries of current technology and necessitate further advancements in data storage and processing capabilities.
The scientific community has received this research with resounding acclaim. Dr. Michael Bienkowski, an assistant professor of physiology and neuroscience, emphasizes the crucial role this project plays in studying the human brain directly, as opposed to relying solely on animal models. Dr. Andreas Tolias, a professor of ophthalmology, highlights the intriguing discovery of highly connected axons, hinting at a previously unknown level of communication within the brain. Dr. Olaf Sporns, a distinguished professor of psychological and brain sciences, sees this project as a crucial step towards mapping the human connectome 바카라 the intricate network of connections that forms the very foundation of our thoughts, behaviors, and memories.
